KR20050080724A - Testing method for a polarizing plate - Google Patents

Abstract

The testing method for polarizers includes two types of testing: a selection beam of light passes through a filter, polarizer, concave lens or filter, mirror, concave lens and finally optical lens; The sample is rotated along the z-axis to see if any deformation of the shade is present in the optical zone to distinguish between good and bad. By applying the method, the shade in the sample is visually identified; The checked result can be reflected to the factory owner. The test cost is cheap and only a cheap tool is needed. Moreover, the process of processing a polarizing plate is further unnecessary.

Description

Testing method for polarizers {TESTING METHOD FOR A POLARIZING PLATE}

The present invention relates to a testing method for polarizing plates. The method involves passing a selection beam of light through a filter, a polarizer, a concave lens or a filter, a mirror, a concave lens and finally an optical lens, wherein the optical film is optical It is rotated along the z-axis to see if any deformation of the shade exists in the zone.

In the polarizing coating process, pre-checking is necessary to prevent product defects and at the same time supply new materials for the light coating. However, there are some defects such as protrusions in the coating that cannot be detected by the naked eye. The projections cause the polarizing coating to have a non-uniform thickness and are not clearly detected with the naked eye until the polarizing coating is pretreated in a semi-finished state, thereby increasing the production cost.

When the light coating is pretreated in a semi-finished state, a check by crossing the transmitted polarizing beam is necessary to confirm the seriousness of the film thickness. It is a recent method to use the checking method because it is less expensive to discriminate between good and bad parts until the coating is semi-finished.

It is difficult to reflect defects to the factory owner who supplies the material of the light coating. The nonuniformity of the film thickness cannot be immediately reflected to the factory owner because the nonuniformity cannot be detected visually until the coating is semi-completed. In addition, there is no exact standard for non-uniformity that is difficult to explain. After all, the factory owner has no idea how to improve on these defects.

The motivation of the present invention is based on the above mentioned, but on the basis of identifying non-uniformities and immediately reflecting them. Therefore, it should not take much time to check the defects. Most importantly, the shortcomings of non-uniform thickness should be revealed, so that the non-uniformity can be detected by the naked eye and no tools for checking are needed.

The present invention relates to a testing method for polarizing plates, the first object of which is to provide a testing method for detecting the non-uniform thickness of the coating by visual observation.

The present invention relates to a testing method for a polarizing plate, the second object of the present invention is to make sure that the thickness is uniform and whether the check result is immediately reflected to the factory owner.

The present invention relates to a polarizing plate testing method, and a third object thereof is to provide a testing method. The cost is not high and there is no need to install additional cost estimating tools and the sample itself can be checked. Therefore, the check method has a simplified procedure and it does not take much time to achieve the check.

The present invention relates to a testing method for polarizing plates. The method involves passing a selection beam of light through a filter, a polarizer, a concave lens or a filter, a mirror, a concave lens and finally an optical lens, wherein the optical film is optical It is rotated along the z-axis to see if any deformation of the shade exists in the zone.

Other features, advantages and advantages of the invention will be apparent from the following description set forth in connection with the accompanying drawings. It is apparent that the above general description and the following detailed description are legends, but do not limit the invention. The accompanying drawings, which are incorporated in and constitute a part of this application, together with the foregoing description serve to explain the principles of the invention in general terms. Like reference numerals refer to like parts throughout the description.

The present invention is directed to providing a testing method for identifying whether there is any shadow in a coating to which a polarized beam is irradiated.

Reference is made to FIGS. 1 and 3, which illustrate a process and apparatus according to a first embodiment. The testing process begins with selecting (101) a light source (11); In step 102, it is checked whether the brightest projection light source 11 for testing has been selected, and if so, proceed to the next step, if not, returning to step 101; In step 103, the sample 26 of the polarizing plate is fixed; In step 104, the selection beam projected from the selected light source 11 passes through a polystyrene (PS) plate 12 to increase the intensity of polarized light; In step 105, the selective beam passes through the PS plate 12 to the filter 13, the filter 13 filters the beam with a suitable range of wavelengths, the range of wavelengths being red, Blue and green light; In step 106, the filtered beam passes through a polarizer 14 to polarize the beam; In step (107), the polarized beam passes through the concave lens (15) to enlarge the beam for easy recognition by the naked eye; In step 108, adjust the sample 16 to adjust the focal length of the light source 11 to form the brightest image for viewing by the naked eye; In step 109, when the focal length is adjusted and the image is in the brightest state, the sample 16 is rotated counterclockwise along a vertical axis; In step 110, the naked eye checks for any deformation of the shade in the optical region, and each sample 16 itself and the image 18 projected onto the screen 17 can be observed; If there is no obvious variant of the shade, proceed to the next step 111; if there is a variant, proceed to step 112; In step 111, classify the good sample and proceed to step 113; In step 112, classify the defective sample; Testing ends at step 113.

Reference is made to FIGS. 2 and 4 which illustrate a process and apparatus according to a second embodiment. The testing process begins with a step 201 of selecting a light source 21; In step 202, it is checked whether the brightest projection light source 21 for testing has been selected, and if so, proceed to the next step, otherwise return to step 201; In step 203, the sample 26 of the polarizer is fixed; In step 204, a select beam passes through to filter 23, the filter 23 filters the beam to a suitable range of wavelengths, the range of wavelengths comprising red, blue and green light; In step 205, the filtered beam is reflected by a mirror 24 to travel up to the concave lens 25 of the beam; In step 206, the reflected beam passes through the concave lens 15 to enlarge the beam for easy visual recognition; In step 207, adjust the sample 26 to adjust the focal length of the light source 21 to form the brightest image for viewing by the naked eye; In step 208, when the focal length is adjusted and the image is in the brightest state, the sample 26 is rotated counterclockwise along a vertical axis; In step 209, the naked eye checks for any deformation of the shade in the optical area, and each sample 26 itself and the image 28 projected onto the screen 27 can be observed; If there is no obvious variant of the shade, go to next step 210; if there is a variant, proceed to step 211; In step 210, classify the good sample and proceed to step 212; In step 211, classify the defective sample; Testing ends at step 212.

The testing method not only checks the non-uniformity of the film thickness, but also allows the identification of scrapes and non-uniform coatings. Another advantage of the method is that it is not expensive to test and no additional expensive tools are needed; In addition, the additional process of the polarizing plate is unnecessary and the sample itself can be checked. Therefore, the testing method has a simplified procedure and does not take much time to achieve the check.

Although the present invention has been described and described with reference to particular embodiments, there is no doubt that the principles can be used in numerous other embodiments that will be apparent to those skilled in the art. Accordingly, the invention will be limited only by the appended claims.

1 is a testing process of a first preferred embodiment of the present invention;

2 is a testing process of a second preferred embodiment of the present invention;

3 is a device of a first preferred embodiment of the present invention;

4 is a device of a second preferred embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

11: light source 12: polystyrene plate

13: filter 14: polarizer

15 concave lens 16 sample

17: screen 18: image

Claims (8)

S1. Selecting a light source; S2. Checking whether the projection light source is selected in the testing, and if the light source is selected, proceeds to S3; otherwise, returns to the S1 state; S3. Fixing the polarizer; S4. Polarizing a beam from the selected light source and projecting the polarized beam onto the polarizer; S5. Adjusting the position of the polarizer to form an image on the polarizer; And S6. Rotating the polarizer to see if there is any change in contrast in the image; Testing method for a polarizing plate comprising a. The method of claim 1, And said polarizing step is selected from the group consisting of reflection and transmission. The method of claim 2, wherein the transmission, Passing the selected beam through a filter; Passing the beam through the filter through a polarizer; And Passing the beam passing through the polarizer through the concave lens; Testing method for a polarizing plate comprising a. The method of claim 3, wherein Passing said beam through a polystyrene plate before said beam passes through a filter. The method of claim 3, wherein And projecting the beam onto a screen after the beam passes through the concave lens. The method of claim 2, wherein the reflection, Passing the selected beam through a filter; Reflecting the selected beam by a mirror after passing the filter; Passing the selected beam through the concave lens after being reflected by the mirror; Testing method for a polarizing plate further comprises. The method of claim 6, And projecting the beam onto a screen after the beam passes through the concave lens. The method of claim 1, And the light source comprises red, blue and green light.